KR101142267B1 - nebulizer assembly - Google Patents

Abstract

The present invention relates to a nebulizer assembly that enables a healthy scalp and hair care by connecting a nebulizer to a helmet to be worn on the head.

Description

Nebulizer assembly

The present invention relates to a nebulizer assembly that enables a healthy scalp and hair care by connecting a nebulizer to a helmet to be worn on the head.

In general, a nebulizer is an aerosolized medicine used for a respiratory disease so that a patient can easily drink the medicine, and an ultrasonic method that physically finens particles using ultrasonic energy, or in a thin nozzle. The chemical liquid sucked by the blowing jet stream is blown out at high speed and hit by an object to break it (Venturi type or Barbington type) to aerosolize the chemical liquid. In addition, by inhaling the particles of the drug solution thus formed into the nose or mouth using the mouthpiece or helmet, the drug solution can reach the end of the bronchus of the patient to cure the disease quickly.

Such nebulizer generally refers to a device that delivers a therapeutic drug into fine particles to treat a respiratory disease such as asthma and bronchitis. Recently, the nebulizer has been widely used in various fields such as medical use and skin care. .

By the way, the nebulizer has a limitation mainly used in connection with the respiratory system or the face.

The present invention has been made to solve the above-described problem, and an object thereof is to provide a nebulizer assembly that can contribute to healthy scalp or hair care.

In order to achieve the above object, the nebulizer assembly according to claim 1 of the present invention,

An air compressor having a suction port and a discharge port; A nebulizer connected to an outlet of the air compressor; helmet; It includes a connector for connecting the helmet and the nebulizer.

According to this configuration, since the nanoparticles are intensively sprayed while the hair is wrapped, the penetration is so fast that the effects such as scalp and hair health are significantly higher than when applied or sprayed.

The nebulizer assembly according to claim 2 of the present invention,

Preferably, the helmet is provided with an air pressure adjusting member.

According to this configuration, it is possible to change the pressure between the helmet and the head by adjusting the air pressure of the nebulizer, so that the penetration rate can be adjusted according to the condition of the scalp or hair.

The nebulizer assembly according to claim 3 of the present invention,

The connector is preferably formed in a bellows shape.

According to this configuration, the connector is stretchable and flexible, thereby increasing user convenience.

The nebulizer assembly according to claim 4 of the present invention,

It is preferable that an oxygen generator is connected to the inlet of the air compressor.

According to the nebulizer assembly of the present invention as described above has the following effects.

Using a helmet, the (almost) airtight penetrates nanoparticles such as aromas, moisture, hair regrowth, and nutrients into the scalp or hair, and is excellent in terms of health care of the scalp and hair.

In addition, by adjusting the air pressure of the nebulizer can give a pressure change between the helmet and the head, it is possible to increase or decrease the penetration rate according to the condition of the scalp or hair.

In addition, the connector is flexible and flexible, thereby increasing user convenience.

In addition, the nebulizer including an input unit for receiving the use of the oxygen generator or the nebulizer, a valve installed between the oxygen generator and the air compressor, and a control unit for controlling the valve by receiving a signal from the input unit, There is no need for a separate air compressor, and when using the nebulizer, the nebulizer can be effectively used by introducing an outside air so that a sufficient flow rate is discharged through the air compressor discharge port to generate a sufficient injection pressure.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

For reference, among the configurations of the present invention to be described below, the same configuration as the prior art will be referred to the above-described prior art, and a detailed description thereof will be omitted.

1 is a perspective view of a nebulizer assembly according to a preferred embodiment of the present invention, FIG. 2 is a perspective view of the nebulizer and a helmet of FIG. 1, and FIG. 3 is an exploded perspective view of the nebulizer and a helmet of FIG. 1.

As shown in FIGS. 1 to 3, the nebulizer assembly 100 of the present embodiment includes an air compressor 300 for sucking and discharging air and a nebulizer 400 connected to the discharge line of the air compressor 300. ), A helmet 600, and a connector 500 connecting the helmet 600 and the nebulizer 400.

The air compressor 300 is provided with an inlet 301 and an outlet 302, and the inlet 301 introduces air from outside air.

In addition, the inlet 301 may be connected to the oxygen discharge unit 201 of the oxygen generator 200 to supply oxygen.

As shown in FIG. 1, the oxygen generator 200 may be provided as a flat membrane-type oxygen generator 200 that separates oxygen from air using a flat membrane. The flat membrane type oxygen generating unit 200 is formed by stacking a plurality of flat membranes at a predetermined interval, and on one side, an oxygen discharge port 201 through which the enriched oxygen is discharged is formed through the flat membrane of each layer.

Unlike the above, the oxygen generator 200 may be applied to other methods, for example, a hollow fiber membrane, a pressure swing adsorption (PSA), a vacuum swing adsorption (VSA), a rapid vacuum swing adsorption (VVSA) method, or the like.

The air compressor 300 generates a vacuum suction force inside the oxygen generator 200 to effectively generate oxygen.

The nebulizer assembly 100 includes an input unit (not shown) receiving input of the use of the oxygen generator 200 or the nebulizer 400, and a valve installed between the oxygen generator 200 and the air compressor 300 ( 250 and a control unit (not shown) for receiving a signal from the input unit to control the valve 250 is preferable.

The input unit receives whether the oxygen generator 200 or the nebulizer 400 is used. The input unit may be provided as a button on an outer surface of a housing (not shown) surrounding the oxygen generator 200 and the air compressor 300. For example, three buttons may be provided, such as an oxygen button, a nebulizer button, and an oxygen + nebulizer button, depending on the type of fluid finally received by the user. When the user presses the oxygen button, the user is finally supplied with only oxygen. When the user presses the nebulizer button, the nebulizer 400 is supplied with a solution filled in, and when the oxygen + nebulizer button is pressed, the nebulizer 400 is pressed. It is supplied with oxygen and solution filled at the same time.

The valve 250 is installed between the oxygen generator 200 and the air compressor 300. The valve 250 allows inflow of outside air to the inlet 301 of the air compressor 300 or blocks inflow of outside air. The valve 250 is preferably implemented by a solenoid valve controlled by a control unit.

The controller receives the signal from the input unit to control the valve 250. That is, open the valve 250 to allow the outside air to flow in, or close the valve 250 to block the outside air from entering.

The nebulizer 400 is connected to the discharge port 302 of the air compressor 300 through a connection hose 305.

As illustrated in FIGS. 2 and 3, the nebulizer 400 includes a solution container 430, a nozzle unit 410, a solution container 430, and a solution container 430 connected to the discharge port 302 of the air compressor 300. It includes a connector 420 connecting the nozzle unit 410.

The solution container 430 includes an outer cylinder 432 and a vent pipe 431 installed inside the outer cylinder 432 and connected to the connection hose 305 so as to communicate with the discharge port 302 of the air compressor 300.

The vent pipe 431 is integrally formed inside the outer cylinder 432, and a space portion 435 having a predetermined volume is formed between the inner wall of the outer cylinder 432 and the outer circumferential surface of the vent pipe 431.

In the space 435, for example, a cosmetic solution containing moisture beneficial to the scalp such as vitamins or moisture, a fragrance solution added with a natural flavor beneficial to the scalp or hair, and a predetermined therapeutic solution (hair regrowth) Can be stored as.

A plurality of fastening protrusions 434 are formed on an outer circumferential surface of the upper end of the outer cylinder 432, and the plurality of fastening protrusions 434 are arranged to be spaced apart from each other along the circumferential direction.

In addition, at the bottom of the outer cylinder 432, a plurality of cutouts 433 are formed in an arc shape, and the plurality of cutouts 433 are arranged to be spaced apart from each other along the circumferential direction.

The vent pipe 431 has a nozzle shape in which the pipe width is narrowed toward the upper portion so as to generate a predetermined injection pressure.

In addition, the outer surface of the vent pipe 431 is formed in an inverted funnel shape so that the cross section becomes smaller toward the top.

The connecting body 420 is connected to the outer cylinder 421 is formed in a cylindrical shape of the upper and lower openings, the outlet is installed on the upper portion of the outer cylinder 421 and formed so that the outer diameter is smaller than the outer cylinder 421 (426).

Connecting body outer cylinder 421 is formed in the upper tapered portion is formed so that the cross-sectional area is smaller toward the upper portion, the lower end of the seating portion 423 is formed with a seating groove for mounting the upper end of the outer cylinder 432 of the solution container 430 Is formed.

In addition, a fastening groove (not shown) in which the fastening protrusion 434 is inserted is formed on the inner wall of the seating part 423, and the connecting body 420 is detachably installed on the solution container 430.

Furthermore, the rib 422 is preferably formed between the seating portion 423 and the connection outer cylinder 421 for rigidity of the connection body 420.

The outlet 426 is installed to penetrate the upper portion of the tapered portion of the outer casing 421, the inductor 425 is horizontally installed at the lower end.

The derivative 425 and the outlet 426 are spaced apart from each other by the support frame 424.

In addition, the derivative 425 is disposed above the vent pipe 431 during assembly.

The solution stored in the space 435 through the outlet 426 is discharged to the outside in the form of fine particles by the pressure discharged through the vent pipe 431.

Further, the diaphragm 440 is disposed between the solution container 430 and the connector 420.

The diaphragm 440 is formed to correspond to the outer shape of the vent pipe 431, is fitted to the upper part of the vent pipe 431, and a through hole 441 penetrates up and down is formed.

In addition, two support protrusions 442 are formed on the outer side of the diaphragm 440 so that the cross-sectional area becomes smaller toward the lower side at intervals of 180 degrees.

The outer surface of the support protrusion 442 faces the inner wall of the outer cylinder 432.

In addition, minute protrusions are formed on the inner wall of the diaphragm 440.

The nozzle unit 410 includes a horizontal pipe part 412 and a vertical pipe part 413 connected to the lower part of the horizontal pipe part 412 and installed to communicate with the outlet 426.

The horizontal tube part 412 is formed so that both ends are open, and the stopper 414 which opens and closes one end or the other end is installed.

The stopper 414 has a hook portion 415 having a through hole formed therein.

The hook portion 415 is provided such that the nebulizer 400 can be fixed to the other member and used, thereby increasing user convenience.

The hook portion 415 is also formed on the horizontal pipe portion 412.

The vertical pipe part 413 is formed to have a larger diameter than the outlet 426 so that the outlet 426 is fitted therein.

Furthermore, the helmet 600 may be provided such that the solution filled in the nebulizer 400 is sprayed on the scalp or hair of the user.

The helmet 600 serves to protect the head as a state of being put on a human head, but when connected to the nebulizer 400, since the head is enclosed to some extent, the nanoparticles are sprayed into the closed space and stay a lot of time. Since a certain amount of pressure is applied to the scalp, heat is applied to the scalp or hair, allowing the particles to penetrate more quickly.

Inside the helmet 600, a space S is formed between a human head and an inner wall of the helmet 600, so that even distribution and penetration of the nanoparticles (particulate solution) are preferably performed.

To this end, as shown in FIG. 3, it is preferable that the mesh body 630 is disposed inside the helmet 600.

The mesh 630 is constituted by a circumferential band 633 which is in contact with the circumference of the head and a length band 631 which is connected in an arc shape in the radial direction of the circumferential band 633.

Therefore, when the helmet 600 is worn after the mesh 630 is worn on the head, as shown in FIGS. 4 and 5, the space S is naturally formed between the length band 631 and the inner wall of the helmet 600. do.

In addition, instead of the length band 631, it may be implemented as a net in the form of a mosquito net.

The circumferential band 633 also supports the length band 631 and also serves to seal the nanoparticles inside the helmet 600 so that they do not leak out.

In the case where the sealing property of the circumferential band 633 is excellent, for continuous penetration of the nanoparticles, it is preferable that pressure adjusting members 700 and 800 for adjusting the pressure are installed as shown in FIGS. 4 and 5.

The pressure regulating member 700 of FIG. 4 preferably includes a pipe 720 in which an exhaust port 710 is formed, and an opening and closing part 730 for opening and closing the exhaust port 710.

A female screw is formed on the inner wall of the tube 720, and the opening and closing portion 730 is composed of a male screw which is fastened to the female screw and a head which turns the male screw.

Therefore, by opening and closing the opening and closing portion 730, by adjusting the opening and closing degree of the exhaust port 710, it is possible to form a pressure according to the health of the scalp or hair.

The pressure regulating member 800 of FIG. 5 is a valve configured to exhaust the space S of the helmet 600 when the pressure exceeds a predetermined pressure.

That is, the pressure regulating member 800 includes a casing 820 having an inlet 810 formed at the front end thereof, a cover 840 having an exhaust port 830 formed at the rear end of the casing 820, and an inlet 810 formed therein. It consists of a ball 850 for opening and closing the spring 860 interposed between the ball 850 and the cover 840.

According to the elastic modulus of the spring 860, the ball 850 may be pushed back according to the pressure of the space S to exhaust the pressure.

In addition, a pressure or a hole of various sizes can be adjusted in the helmet 600 as the pressure regulating member.

On the other hand, it is preferable that the detachable member 635 for detachably fixing the mesh 630 to the helmet 600 is formed.

The detachable member 635 is preferably constituted by a hook protrusion 635a provided on the circumferential band 633, and a hook groove 635b on which the hook protrusion 635a is detachably hooked.

Therefore, the hook protrusion 635a is caught when the hook groove 635b falls down from the top, and on the contrary, when the hook protrusion 635a is pulled up, the hook protrusion 635a is widely used in a general motorcycle helmet.

In addition, a connector 500 for connecting the helmet 600 and the nebulizer 400 may be further provided.

The connector 500 has an enlarged diameter portion 510 having a larger diameter than the horizontal tube portion 412 at one end thereof, so that the horizontal tube portion 412 is connected, and a groove 532 into which the helmet 600 is fitted around the other end thereof. The formed sealing part 531 is formed so that the helmet 600 is connected.

For example, the sealing part 531 may be formed in a flange shape, formed to correspond to the shape of the helmet 600 and bent, and may be formed of a flexible material such as rubber.

When the sealing part 531 is fitted to the helmet 600, the end of the sealing part 531 is contracted and then pushed into the through hole 620 of the helmet 600 so that the periphery of the through hole 620 is notched in the groove 532. To be fitted.

As such, the helmet 600 is fitted into the groove 532, and the sealing part 531 is disposed inside and outside the helmet 600, respectively.

Therefore, the sealing can be effective, and the sealing portion 531 can be easily detached to the through hole 620 of the helmet 600, even if the user moves during use, the sealing portion 531 is a helmet 600 There is an advantage that does not easily deviate from.

In addition, the connector 500 is formed in a bellows shape between the enlarged diameter part 510 and the sealing part 531 to form a flexible and stretchable bellows part 520.

As described above, the bellows portion 520 is formed so that the connector 500 is stretchable and flexible, thereby increasing user convenience.

The operation of this embodiment having the above-described configuration will be described below.

First, after placing the diaphragm portion 440 between the vent pipe 431 and the outer cylinder 432, the solution is placed in the space portion 435, the connector 420 is placed on top of the solution container 430, and then connected The fastening protrusion 434 is fitted into the fastening groove of the connecting body 420 by rotating the sieve 420.

When the user presses the oxygen + nebulizer button of the input unit, the air compressor 300 and the oxygen generator 200 operate to discharge oxygen through the oxygen discharge unit 201, and the valve 250 is controlled by the controller. When open, oxygen and outside air are simultaneously introduced into the inlet 301 of the air compressor 300 by the suction force of the air compressor 300. The introduced oxygen and the outside air are discharged through the discharge port 302 of the air compressor 300 and then transferred to the vent pipe 431 of the nebulizer 400 through the connection hose, and then hit the inductor 425 and the space 435. Is supplied to the solution in the space portion 435 is in the form of particulates, is transferred between the support frame 424, discharged to the discharge port 426 to the horizontal pipe portion 412 of the nozzle portion 410 do. Subsequently, oxygen is contained and the solution in particulate form is supplied to the helmet 600 through the connector 500.

When the user presses the oxygen button of the input unit, the air compressor 300 and the oxygen generator 200 operate to discharge oxygen through the oxygen discharge unit 201, and the valve 250 is closed by the control unit so that only oxygen The suction force of the air compressor 300 is simultaneously introduced into the inlet 301 of the air compressor 300. As such, when the user uses only oxygen, the nebulizer 400 may be removed and the discharge port 302 of the air compressor 300 may be directly connected to the helmet 600.

When the user presses the nebulizer button of the input unit, the air compressor 300 is operated and the valve 250 is opened by the control unit so that the outside air is inlet 301 of the air compressor 300 by the suction force of the air compressor 300. Flows into). The subsequent procedure works the same as when the user presses the oxygen + nebulizer button.

As such, when the nebulizer 400 is used, the valve 250 is opened by the controller so that the outside air flows into the inlet 301 of the air compressor 300 by the suction force of the air compressor 300, and the solution is injected at a sufficient injection pressure. There is an advantage. In addition, since the nebulizer 400 and the oxygen generator 200 may be simultaneously used through one air compressor 300, the device cost is reduced and the device is compact.

Hereinafter, the oxygen generator assembly control method of the present embodiment having the above-described configuration will be described.

The control method of the nebulizer assembly 100 includes an input step of receiving an input of using the oxygen generator 200 or the nebulizer 400 and an air connected to the oxygen generator 200 when receiving the use of the oxygen generator 200. By preventing outside air from flowing into the compressor 300, oxygen is discharged into the discharge port 302 of the air compressor 300, and when the use of the nebulizer 400 is input, air is introduced into the air compressor 300 so that the nebulizer is introduced. And an outside air control step of causing the outside air to be discharged to the discharge port 302 of the air compressor 300 to which the 400 is connected.

The input step receives whether the oxygen generator 200 or the nebulizer 400 is used through the input unit such as the oxygen button, the nebulizer button, or the oxygen + nebulizer button.

The outside air control step is connected to the oxygen generating unit 200 by closing the valve 250 when the control unit receives a signal from the input unit, and receives the use of the oxygen generating unit 200 as the oxygen button is pressed by the user The outside air is prevented from flowing into the inlet 301 of the air compressor 300 so that oxygen is discharged to the outlet 302 of the air compressor 300. In addition, when the user inputs the use of the nebulizer 400 such that the nebulizer button or the oxygen + nebulizer button is pressed by the user, the valve 250 is opened to introduce external air into the inlet 301 of the air compressor 300. The outside air is discharged to the discharge port 302 of the air compressor 300 to which the nebulizer 400 is connected.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified or modified within the scope of the invention without departing from the spirit and scope of the invention described in the claims below. It can be modified.

For example, the pressure control valve of the present invention is formed in the helmet, but can be installed in front of or behind the nebulizer 400 to adjust the pressure.

In addition, a configuration for massaging the scalp or a configuration for warming / humidifying the scalp may be added to the inside of the helmet.

As described above, the present invention is suitable for the nebulizer assembly for cosmetic or medical.

1 is a perspective view of a nebulizer assembly according to a preferred embodiment of the present invention.

2 is a perspective view of the nebulizer and helmet of FIG.

3 is an exploded perspective view of the nebulizer and the helmet of FIG. 1.

4 is a sectional view of one embodiment of a pressure regulating valve.

5 is a sectional view of another embodiment of the pressure regulating valve.

** Description of symbols for the main parts of the drawing **

100: nebulizer assembly 200: oxygen generator

250: valve 300: air compressor

400: Nebulizer 500: Connector

600: helmet 630: mesh

635: fixing member 700, 800: pressure regulating valve

Claims (4)

delete An air compressor having an inlet and an outlet; A nebulizer connected to an outlet of the air compressor; helmet; A connector connecting the helmet and the nebulizer; Including a pressure adjusting member 800 is installed in the helmet, The pressure regulating member 800 includes a casing 820 having an inlet 810 formed at a front end thereof, an exhaust port 830 formed at a rear end of the casing 820, and a cover 840 provided at the rear end of the casing 820. Nebulizer assembly consisting of a spring (860) interposed between the ball (850) for opening and closing the, and the ball (850) and the cover (840). 3. The method of claim 2, The connector is a nebulizer assembly formed in a bellows shape. The method according to claim 2 or 3, Nebulizer assembly is connected to the oxygen generating portion inlet of the air compressor.

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